Center vortex

Center vortices are line-like topological defects that exist in the vacuum of Yang–Mills theory and QCD. They seem to play an important role in the confinement of quarks.

In SU(N) theories

Center vortices are line-like topological defect that carry a gauge charge equal to one of the center elements of the gauge group. In the case of SU(N) gauge theories, these are the constant matrices:

z_n = e^{\frac{2\pi in}N} I\;,

where I is the unit matrix. These elements form the abelian subgroup ZN. Under such center elements, quarks transform as

\psi \to e^{\frac{2\pi in}N}\psi\;,

while gluons are invariant. This means that, if quarks are free (like in the deconfined phase), the center symmetry will be broken. Restoration of the center symmetry will imply confinement. 't Hooft first put this on a more rigorous footing.[1]

The two phases in the theory can be distinguished based on the behavior of the vortices.[2] When considering a certain Wilson loop, if the vortices are generally long, most vortices will only pierce the surface within the Wilson loop once. Furthermore the number of vortices piercing this surface will grow in proportion to the area of the surface. Due to the vortices suppressing the value of the vacuum expectation value of the Wilson loop, this will lead to an area-law, i.e. the Wilson loop W(C) behaves like

\langle W(C)\rangle \propto e^{-\sigma A}\;,

where A is the area spanned by the loop. The constant σ is called the string tension. This behavior is typical of confinement. However, when considering a regime where vortices are generally short i.e. they form small loops they will usually pierce the surface of the Wislon loop twice in opposite directions, thus leading to the two contributions canceling. Only vortex loops near the Wilson loop itself will pierce it once, thus leading to a contribution scaling like the perimeter:

\langle W(C)\rangle \propto e^{-\alpha L}\;,

with L the length of the Wilson loop, and α some constant. This behavior signals there is no confinement.

In lattice simulations this behavior is indeed seen.[2] At low temperatures (where there is confinement) vortices form large, complex clusters and percolate through space. At higher temperatures (above the deconfinement phase transition) vortices form small loops. Furthermore it has been seen that the string tension almost drops to zero when center vortices are removed from the simulation.[3] At the other hand, the string tension remains approximately unchanged when removing everything except for the center vortices. This clearly shows the close relation between center vortices and confinement. Aside from this it has also been shown in simulations that the vortices have a finite density in the continuum limit (meaning they are not a lattice artifact, but they do exist in reality), and that they are also linked with chiral symmetry breaking and topological charge.[3]

One subtlety concerns the string tension at intermediate range and in the large-N limit. According to the center vortex picture, the string tension should depend on the way the matter fields transform under the center, i.e. their so-called N-ality. This seems to be correct for the large-distance string tension, but at smaller distances the string tension is instead proportional to the quadratic Casimir of the representation so-called Casimir scaling. This has been explained by domain formation around center vortices.[4] In the large-N limit, this Casimir scaling goes all the way to large distances.[5]

In gauge theories with trivial center

A gauge group like SO(3) has a trivial center, but SO(3) gauge theory is expected to be identical to SU(2) gauge theory. This discrepancy is due to the fact that, rather than the center, it is really the homotopy group π1 which should be considered.[5] Also mark that a theory like G2 gauge theory does not have a long-range string tension, which is consistent with the center vortex picture. In this theory, gluons can screen quarks, leading to color singlet states with the quantum number of quarks. Casimir scaling is, however, still present at intermediate ranges, i.e. before string breaking occurs. This can be explained by domain formation.[4]

See also

References

  1. G. 't Hooft (1978). "On the phase transition towards permanent quark confinement". Nucl. Phys. B138: 1. Bibcode:1978NuPhB.138....1T. doi:10.1016/0550-3213(78)90153-0.
  2. 1 2 M. Engelhardt; K. Langfeld; H. Reinhardt; O. Tennert (2000). "Deconfinement in SU(2) Yang-Mills theory as a center vortex percolation transition". Phys. Rev. D61: 054504. arXiv:hep-lat/9904004. Bibcode:2000PhRvD..61e4504E. doi:10.1103/PhysRevD.61.054504.
  3. 1 2 M. Faber; J. Greensite; Š. Olejník (2001). "Direct laplacian center gauge". JHEP 11: 053. arXiv:hep-lat/0106017. Bibcode:2001JHEP...11..053F. doi:10.1088/1126-6708/2001/11/053.
  4. 1 2 J. Greensite; K. Langfeld; Š. Olejník; H. Reinhardt; T. Tok (2007). "Color screening, Casimir scaling, and domain structure in G(2) and SU(N) gauge theories". Phys. Rev. D75: 034501. arXiv:hep-lat/0609050. Bibcode:2007PhRvD..75c4501G. doi:10.1103/PhysRevD.75.034501.
  5. 1 2 J. Greensite (2003). "The confinement problem in lattice gauge theory". Prog. Part. Nucl. Phys. 51: 1. arXiv:hep-lat/0301023. Bibcode:2003PrPNP..51....1G. doi:10.1016/S0146-6410(03)90012-3.
This article is issued from Wikipedia - version of the Wednesday, February 29, 2012. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.